DE1991542U - Automatic ice cube maker - Google Patents

Description

The innovation relates to an automatic ice cube maker for household refrigerators. Such an ice cube maker is described in U.S. Patents 3,163,017 and 3,163,018 dated Dec. 29, 1964. An ice cube maker of this type has a shape with at least one cavity in which an ice cube is formed. Furthermore, an ejector with a punch is provided, which is normally is arranged in the lower part of the cavity and can be raised above the upper edge of the cavity in order to eject a piece of ice from the cavity. Furthermore, a pivotably arranged scraper is also provided, which is actuated when the piece of ice has been lifted all the way up. This scraper is moved across the top of the cavity of the mold in order to scrape the piece of ice off the punch and push it into a storage container which is arranged a little lower on one side of the mold. The scraper is in the ice cube maker, which is described in the two above-mentioned patents, pivoted around an axis above the cavity, and it is moved from its normal position on the lower side of the cavity on a curved path to a position above of the cavity. The scraper is driven by the same motor as the ejector. In order to be able to break away the ice cube from the ejector with sufficient force, a reduction gear is provided so that the scraper moves relatively slowly.

Since the scraper moves slowly over the mold, the ice cube is only pushed over the edge of the mold, so that practically all the ice cubes pile up next to the mold instead of being spread over the entire storage container.

The innovation now includes an ice cube maker of the type described above with an improved scraper, which ensures that the ejected ice cube is stripped from the upper edge of the mold at such a speed that the ice cubes are distributed more evenly in the storage container. For this purpose, the scraper has a pivotably mounted drive so that the scraper is moved from its normal position on the rear side of the cavity of the mold into a position where the ice cube is broken free from the ejector, and also a spring mechanism that during the movement of the scraper is actuated and an ice cube is accelerated so that it is thrown over the front edge of the mold.

In the following, the innovation will be described in detail in conjunction with the drawings.

Fig. 1 is a side view of an ice cube maker according to the invention.

Figure 2 is a section taken on line 2-2 of Figure 1;

Fig. 3 is a section along the line 3-3 of Fig. 1 and shows the position of certain components of the ice cube maker at the beginning of the stripping process, and

FIG. 4 is a representation similar to FIG. 3 and shows the position of certain components of the ice cube maker at a later point in time.

The ice cube maker shown in the figures has a shape 1 which can be screwed with one or more screws 2 to a wall of the freezer compartment of a household refrigerator. The mold has several cylindrical cavities 3 for the ice, which are arranged in a straight line and separated from one another by partitions 4. Each partition is provided with a vertical channel 5 so that water can flow from one cavity into the other cavity when the mold is filled with water. Furthermore, a number of punches 6 are provided, some of which form the bottom of the cavities 3. These punches are slidably arranged in the channels 5 and are connected to one another by a cross bar.

The drive and control devices for the ice cube maker are housed in a housing 9 which is attached to one end of the mold. These include a motor 10, a lever 11 and a rod 12, by means of which the punches 6 with the pieces of ice 14 can be raised when the pieces of ice 14 are to be removed from the cavities 3 of the mold.

The ice cube maker has an elongated scraper 15 which extends along the entire mold 1. The scraper is normally arranged on the rear side of the cavities, as shown in FIG.

The scraper has arms or extensions 16 which extend forward and are pivotally mounted by the pins 17, above the mold or, more precisely, above the cavities 3. If the scraper is now rotated around the pins 17 parallel to the cavities it moves from its normal position on the back of the cavity and grabs the pieces of ice lying on the punches 6 and then swings over the space above the cavities so that the pieces of ice are stripped off the punches 6 and into a storage container or - fall basket 18, which is arranged below the mold.

The mode of operation of the automatic ice cube maker has been described in detail in the US patents mentioned at the beginning. For automatic ice cube preparation, the cavities 3 are filled with water. The mold is then heated in order to free the pieces of ice that have formed from the mold. Then the punches 6 are pushed up from their lowest position, until they protrude slightly above the top surface 19 of the mold. Now the scraper 15 is swiveled over the top of the mold and engages the ejected pieces of ice 14 and wipes them off. The stripper and the punches 6 are now returned to their original position, and the mold is again filled with water. This work cycle is repeated until the ice production is ended when a sensor arm 20 detects that a certain ice height in the storage container 18 has been reached.

Since one or more pieces of ice can be frozen to the punches 6 when the pieces of ice are lifted above the surface 19 of the mold, the drive of the scraper must be designed in such a way that such a strong force can be exerted that the pieces of ice are removed from the punches 6 can be broken loose. In the ice cube maker according to the US patents mentioned above, the motor 10 is connected to a cam disk 22 via a reduction gear so that this cam disk 22 is driven with increased torque. This cam disk 22 actuates a lever 23, the free end of which is connected to a rod 24. The upper end of the rod 24 is connected to a further lever 25, which in turn is directly connected to the scraper 15, so that the

Up and down movement of the rod 24 causes a reciprocating pivoting movement of the scraper. The reduction gear causes the scraper to move relatively slowly and the pieces of ice being scraped from the surface of the mold fall just over the front edge 28 of the mold and pile up just below the front edge 28 of the mold. The sensor arm 20 therefore detects this accumulation of pieces of ice, and ice making is stopped, regardless of whether the entire storage container 18 is filled with pieces of ice or not. According to the innovation, a more even distribution of the pieces of ice in the storage container 18 is achieved by an improved scraper, which scrapes the pieces of ice more strongly from the surface of the mold, so that they fall into more distant parts of the storage container 18.

In the embodiment shown, the scraper 15 is arranged in a cantilevered manner on its pin 17, i. H. it is not directly connected to the drive lever 25. The desired reciprocating movement of the scraper 15 is achieved by a drive part or yoke 30 which is keyed on a shaft 31 which is arranged coaxially with the pivot axis of the scraper 15 and which is directly connected to the lever 25.

The drive part 30 has an arm 32 which engages at one end of the scraper on the upper edge 33 of the scraper 15, as well as a further arm 35, the end portion 36 of which engages the lower front edge 37 of the scraper during certain phases of the working cycle. The drive part 30 is constructed in such a way that only the arm 32 or only the arm 35 engages the scraper 15 during the ice making.

When the scraper 15 is in its normal or rearward position, as shown in FIGS. 2 and 3, its lower edge 37 lies behind the cavities 3, and the drive part 30 is in the position indicated by dashed lines in FIG. The arm 35 engages the lower edge 37 of the scraper. When pieces of ice are to be removed from the mold and the punch 6 has lifted the pieces of ice out of the cavities, the drive part 30 is rotated clockwise. As a result, the upper arm 32 engages the upper edge 33 of the scraper, as shown in FIG. 3, so that the movement of the scraper for gripping the pieces of ice 14 is triggered. The scraper continues to move counterclockwise until the pieces of ice are detached from the punches and stripped from the surface of the mold. Thereafter, the drive part 30 is moved in the opposite direction, so that the end portion

36 of the arm 35 engages the scraper and returns it to its starting position.

Since the drive part 30 moves relatively slowly, the speed of the pieces of ice that is transmitted to them by the movement of the drive part 30 is also very low. Therefore, the pieces of ice can only fall over the leading edge of the mold. In order to be able to scrape off the pieces of ice at a higher speed so that they are distributed more evenly in the storage container 18, the scraper 15 has a spring mechanism which is stretched out of its rearward position during the initial movement of the scraper, but then releases this energy, to accelerate the scraper so that the pieces of ice fall off the surface of the mold at a higher speed.

The illustrated spring mechanism is a snap spring mechanism connected to the opposite end of the scraper 15 as shown in FIG. The snap spring mechanism includes a tension spring 40, one end of which is anchored to the nose 41 of a protrusion which extends forwardly from the front of the mold. The other end of the spring is connected via a lever 43 to an arm 44 which rests on the stripper 15 on the drive part 30 opposite end is provided. The normal position of the scraper 15, the lever 43 and the spring 40 is indicated in FIG. 2 by solid lines. While the scraper 15 initially moves forward, as shown in FIG. 4, the pin 45, which connects the lever 43 to the arm 44, moves counterclockwise, as shown in FIG. As a result, the spring 40 is tensioned until the pivot point 45 is displaced beyond the pivot point 17 of the scraper. Now the energy stored in the spring 40 is released, so that the scraper 15 moves forward faster under the action of the spring 40 and the pieces of ice 14 are pushed down by the scraper 15 at a higher speed from the top of the mold and into more distant parts of the mold Storage container 18 fall, as shown in Fig. 4.

If the movement of the drive part 30 takes place in the opposite direction, the arm 35 grasps the lower edge 37 of the scraper and guides it back into its starting position or normal position behind the cavities 3. The scraper is now ready for use again. This snap spring mechanism now also serves to hold the scraper in its normal position.

The snap spring mechanism is preferably designed so that the scraper 15 moves relatively slowly during it is pushed forward by the arm 32 of the drive part, and the end section 36 of the drive part moves away from the lower edge 37 of the scraper 15. In this way, the scraper 15 can grasp the pieces of ice and release them from the stamps before the snap spring mechanism takes effect. After the pieces of ice have been detached from the punches 6 by the scraper, which moves relatively slowly, the snap spring mechanism becomes effective and drives the detached pieces of ice off the surface of the mold so quickly that they do not pile up directly below the mold. It should be noted that the scraper only moves over a relatively short distance at increased speed, because it is then braked in that its lower edge rests against the end section 36 of the drive part 30, as shown in FIG. 4.

From the above description it can be seen that the innovation is an improved scraper, which makes it possible to optimally distribute pieces of ice in relatively large storage containers. Since the more distant parts of the container are now also filled with pieces of ice, the pieces of ice lying next to the already piled up gradually pile up in the direction of the sensor, which registers the desired ice height in the container.

Claims (6)

1. Automatic ice cube maker with a mold with freezer cavities, in which upwardly movable ejectors are arranged, through which the ice cubes formed can be lifted from the freezer cavities to a position above the mold, further with a scraper, which can be pivoted above the mold and from a Position behind the freezer cavities in a position above the freezer cavities and engages in this movement on the raised pieces of ice and scrapes them from the mold, and with a drive device for the scraper, which by a movement in one direction, the scraper in the position above moves the freezer cavities and when moving in the other direction brings the scraper back into the starting position behind the freezer cavities, characterized in that a spring device is provided which during the initial movement of the scraper into its position above the freezer cavities i st and whose energy is then released, so that the pieces of ice have knocked off the neighboring edge of the mold. 2. Ice cube maker according to claim 1, characterized in that the raised pieces of ice are breakable by the stripper during the initial phase of its pivoting movement from the ejector stamps. 3. Ice cube maker according to claim 1 or 2, characterized in that the energy stored in the spring device is released after the scraper has attacked the pieces of ice. 4. Ice cube maker according to claim 1, 2 or 3, characterized in that the spring device is a snap spring mechanism. 5. Ice cube maker according to claim 1, characterized in that the drive device for the scraper is provided with a reciprocating intermediate member with two legs, one leg of which has a certain distance in the initial position of the scraper from the scraper and in the initial phase of the movement the drive device engages the scraper in one direction, so that the scraper is moved by this leg into its position above the freezer cavities, the other leg of which is at a certain distance from the scraper when the scraper is moved into its position above the freezer cavities and in the Reversal of the direction of movement the drive device engages on the scraper, so that the scraper is then moved back from the second leg into its starting position, that the spring device is connected to the scraper, so that the spring device is tensioned during the initial movement of the scraper at a speed that corresponds to the speed corresponds to the drive device, and that by releasing the energy stored in the spring device, the speed of the scraper is increased from its way into its position above the freezer cavities, so that the ice pieces are pushed down over the adjacent edge of the mold. 6. Ice cube maker according to claim 5, characterized in that the scraper is pivotably mounted at both ends, that the drive device engages at one end of the scraper, and that the spring device is connected to the other end of the scraper.